Large Temperature-Independent Magnetoresistance without Gating Operation in Monolayer Graphene

Authors
Jeon, JihoonLee, Duk HyunKim, Yeon SooChung, Hyun-JongJhang, Sung HoKwon, YongkyungLee, SuyounPark, Bae Ho
Issue Date
2020-11-25
Publisher
American Chemical Society
Citation
ACS Applied Materials & Interfaces, v.12, no.47, pp.53134 - 53140
Abstract
Temperature-independent magnetoresistance (TIMR) has been studied for applications in magnetic field sensors operating in wide temperature ranges. Graphene is considered as one of the best candidates for achieving nonsaturating and large TIMR through engineering disorders. Nevertheless, large TIMR has not been achieved in disordered graphene with intrinsic defects, such as chemical doping and atomic dislocations. In this work, by introducing extrinsic defects, we realize nonsaturating and large TIMR in monolayer graphene transferred on a BiFeO3 nanoisland array (G/BFO-NIA). Furthermore, the G/BFO-NIA device exhibits a significantly larger MR (similar to 250% under 9 T) than other materials without gating operation, demonstrating its application feasibility. It is shown that the large MR is a result of the coexistence of electrons and holes with almost the same density, and the observed TIMR originates from the temperature dependence of carrier transport in graphene and of the dielectric property of BFO-NIA.
Keywords
temperature-independent magnetoresistance; disorder; graphene; BiFeO3 nano-island array; without gating
ISSN
1944-8244
URI
https://pubs.kist.re.kr/handle/201004/117823
DOI
10.1021/acsami.0c16083
Appears in Collections:
KIST Article > 2020
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